Electric power control system and efficiency optimization process for polyphase synchronous machine

ABSTRACT

A system and process includes continuously determining an applied armature voltage supplied to a polyphase synchronous machine for which a maximum mechanical load is characterized by a pull-out torque. The armature voltage is supplied from a power source via one of many taps of a regulating transformer. The armature voltage being supplied from the power source to the machine is changed by selecting one of the voltage levels from the taps of the regulating transformer. The tap voltage levels are selected based on the determined applied armature voltage to minimize power consumption of the machine while ensuring based on a predetermined confidence level that the pullout torque of the machine will not be exceeded.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is related to, claims the earliest availableeffective filing date(s) from (e.g., claims earliest available prioritydates for other than provisional patent applications; claims benefitsunder 35 USC §119(e) for provisional patent applications), andincorporates by reference in its entirety all subject matter of thefollowing listed application(s); the present application also claims theearliest available effective filing date(s) from, and also incorporatesby reference in its entirety all subject matter of any and all parent,grandparent, great-grandparent, etc. applications of the followinglisted application(s):

1. United States patent application entitled ELECTRIC POWER CONTROLSYSTEM AND PROCESS, naming David G. Bell as inventors, filedsubstantially contemporaneously herewith.

2. U.S. patent application Ser. No. 11/397,091, entitled ELECTRICALPOWER DISTRIBUTION CONTROL SYSTEMS AND PROCESSES, naming David G. Bell;Thomas L Wilson; and Kenneth M. Hemmelman as inventors, filed Apr. 4,2006.

3. U.S. patent application Ser. No. 12/540,366, entitled ELECTRIC POWERCONTROL SYSTEM AND EFFICIENCY OPTIMIZATION PROCESS FOR A POLYPHASESYNCHRONOUS MACHINE, naming David Gordon Bell as inventor, filed Aug.13, 2009.

4. U.S. patent application Ser. No. 13/784,069, entitled ELECTRIC POWERCONTROL SYSTEM AND EFFICIENCY OPTIMIZATION PROCESS FOR A POLYPHASESYNCHRONOUS MACHINE, naming David Gordon Bell as inventor, filed Mar. 4,2013.

TECHNICAL FIELD

These claimed embodiments relate to a method for regulating electricpower being supplied to adjusting voltage levels of electric powerprovided to a polyphase synchronous machine based on estimatesdetermined from the machine's loads power consumption.

BACKGROUND OF THE INVENTION

A method and apparatus for regulating electric power being supplied to apolyphase synchronous machine under load is disclosed.

When supplying power to a polyphase synchronous machine that consumes atremendous amount of electrical power, several needs compete and must besimultaneously considered in managing its electrical power distribution.A first concern has to do with maintaining delivered electrical powervoltage levels within predetermined limits. A second concern relatesimproving overall efficiency of electrical power usage and distribution.A third concern relates to these and other concerns in light of changingelectrical loading of the machine and variations in the character of theloading so that the voltages do not decrease to such a level that thesynchronous machine enters a state known as pull-out, in which thestator and rotor magnetic fields fail to maintain mutual engagement,characterized by the rotor field slipping out of engagement with therotating magnetic field of the stator. This condition, commonly known aseither pull-out or pole slip, can result in damage to the machine. Themechanical load condition at which pull-out or pole slip occurs is knownas the pull-out torque.

One technique to accommodate changes in electrical loading is to setpreset threshold levels at high enough levels at which pull-out is notlikely to occur. Although this technique provides a margin of safety forthe machine, it results in inefficiencies as the voltage of the systemmust be kept sufficiently high at all times even when the machine is notunder a high load. Thus for an energy efficiency standpoint, a lot ofenergy is wasted providing unnecessarily high margins of safety.

SUMMARY OF THE INVENTION

A process is described in which an applied armature voltage supplied toa polyphase synchronous machine is continuously determined. The armaturevoltage is supplied from a power source via one of a plurality of tapsof a polyphase regulating transformer. For the purpose of clarity, allreferences to regulators or regulating transformers shall be inclusiveof polyphase regulators. Each of the tap settings supplies a voltage ata different level. The armature voltage being supplied from the powersource to the machine is changed by selecting one of the voltage levelsfrom the taps of the regulating transformer. The selection of one of thevoltage levels is based on the determined applied armature voltage tominimize power consumption of the machine while ensuring, based on apredetermined confidence level, that the resulting pull-out torque ofthe machine will not be exceeded by the mechanical load.

In another implementation, a system is disclosed including a regulatingtransformer having taps that provide different output voltage levelsrespectively when connected to a power source. Each tap when selectedcan apply an armature voltage to a polyphase synchronous machine. Thesystem includes a controller that continuously determines an actualapplied armature voltage supplied to the polyphase synchronous machineand that provide a signal to change the applied armature voltagesupplied to the polyphase synchronous machine by selecting one of thetaps to minimize power consumption of the machine while ensuring withina predetermined confidence level that a pull-out torque of the machineis not exceeded.

In addition, a computer readable storage medium comprising instructionsis disclosed. The instructions when executed by a processor is coupledwith a regulating transformer having taps that provide different outputvoltage levels respectively when connected to a power source. Each tapwhen selected applies an armature voltage to a polyphase synchronousmachine. The instructions when executed include continuously determiningan actual applied armature voltage supplied to the polyphase synchronousmachine, and providing a signal to change the applied armature voltagesupplied to the polyphase synchronous machine by selecting one of thetaps to minimize power consumption of the machine while ensuring withina predetermined confidence level that a pull-out torque of the machineis not exceeded.

BRIEF DESCRIPTION OF THE DRAWINGS

The detailed description is described with reference to the accompanyingfigures. In the figures, the left-most digit(s) of a reference numberidentifies the figure in which the reference number first appears. Theuse of the same reference number in different figures indicates similaror identical items.

FIG. 1 is a simplified schematic diagram of an electric power controlsystem for regulating power;

FIGS. 2 a-2 c are simplified schematic diagrams of voltage signalprocessing elements that processes measured voltage signals to provideselected voltage signals for tap regulation;

FIGS. 2 d-2 e describe the voltage adjustment decision processesimplemented by voltage controller shown in FIG. 1; and

FIG. 3 is a simplified schematic diagram of a voltage controller shownin FIG. 1.

FIG. 4 is a flow chart determining a voltage adjustment decision byvoltage controller shown in FIG. 3.

FIG. 5 is a diagram illustrating a typical probability distribution ofthe voltage control system that is used to select a weighting factorthat is used in estimating consumed power deviations.

DETAILED DESCRIPTION

Referring to FIG. 1 there is shown a electric power control system 100having power source 101 connected via a subsystem transmission bus 102and via substation transformer 104 to a voltage regulating transformer106. Voltage regulating transformer 106 is controlled by voltagecontroller 108 with regulator interface 110. Voltage regulatingtransformer 106 is coupled on primary distribution element or circuit112 via distribution transformer 121 to utilization circuits 116 and toa polyphase synchronous machine 119. Voltage regulating transformer 106has multiple tap outputs (not shown) with each tap output supplyingelectricity with a different voltage level. In an AC Power distributionsystem and as used herein voltage may be generally is referred to as an“RMS Voltage”.

Monitoring device 118 is coupled through potential transformer 120 tosecondary utilization circuit 116. Monitoring device 118 includes ameasurement circuit, signal sampling and signal buffering circuits, anda communications interface circuit. Monitoring device 118 continuouslydetects measurements and continuous voltage signals of electricitysupplied to a polyphase synchronous machine 119 connected to circuit 112or 116 from a power source 101 coupled to bus 102. Monitoring device 118is coupled via communications media 122 to voltage controller 108.

Voltage controller 108 determines an actual applied armature voltagesupplied to the polyphase synchronous machine. Controller 108 provides asignal to voltage regulating transformer 106 via regulator interface 110to change the applied armature voltage supplied to the polyphasesynchronous machine by selecting one of the plurality of taps intransformer 106 to minimize power consumption of the machine whileensuring within a predetermined confidence level that a pull-out torqueof the machine is not exceeded. Voltage controller 108 includes avoltage signal processing circuit 126 that receives sampled signals frommetering device 118. Metering device 118 processes and samples thecontinuous voltage signals such that the sampled voltage signals areoutputted as a uniformly sampled time series that are free of spectralaliases. Such a metering device having this process and samplecapability is generally commercially available.

Voltage signal processing circuit 126 receives voltage, current, realpower, and reactive power signals via communications media from meteringdevices 118 processes the signals and feeds them to voltage adjustmentdecision processor element or circuit 128. Voltage signal processingcircuit 126 and Adjustment decision processor circuit 128 determinescharacteristics of the synchronous machine that are predicted to beaffected by future changes in the voltage levels provided from thevoltage regulating transformer 106. Examples of these characteristicsinclude a slip of the synchronous machine, an estimated torque demand, amargin of pull-out torque, and a forecast maximum mechanical torquedemand.

Details of these determinations are explained in more detail herein. Inresponse to these determinations, the voltage controller 108 provides asignal to via regulator interface 110 to set the tap position. As thecomputed estimated torque demand, margin of pull-out torque, forecastmaximum mechanical torque demand, vary in time due to changing machineload, the voltage level of the electricity supplied to the synchronousmachine 119 is changed.

Referring to FIGS. 2 a and 2 b, in which an exemplary three phase powersystem and synchronous machine is depicted in voltage signal processingelement 200 (signal processing block 126 in FIG. 1). Element 200 isshown including RMS averaging elements 201, Power angle detectionelements 203, Power variance elements 205, and torque estimatingelements 207. Referring to FIG. 2 a, RMS averaging elements 201 receivesvoltage levels V_(AB), V_(BC), and V_(CA) from metering device 118,wherein the subscript letters indicate the utilization circuit phasesacross which the voltages are measured and determines an Average Voltagesignal (V_(AVG)). Power angle detection elements 203 receives a signalindicating the Armature reactive power (Q) and a signal indicating theArmature real power (P) from metering device 118 and generates a powerangle (φ). Power variance elements 205 receives a signal indicating theArmature real power (P) from metering device 118 and generates (P_(LP))delay compensated linear phase low pass filtered Armature real demand,smoothed peak envelope Armature real demand, (P_(PK)), P_(VAR) thevariance of the Armature real demand.

RMS averaging elements 201 includes three parallel low pass filter/delaycompensate elements (202/204, 208/210, and 212/214) connected to theinput of RMS average integrator element 206. Delay Compensate element204 (as well as 210 and 214) is fed the output of the low pass filter202 (as well as 298 and 212) where the signal or an estimate of thesignal from the respective filter is extrapolated in time such that thedelay resulting from the low pass filtering operation is removed.

Power angle detection elements 203 include low pass filter 216 connectedvia delay compensate element 218 to one terminal of power anglecomparator 220. Power angle detection elements 203 also includes lowpass filter 216 connected via compensate circuit element 218 to anotherterminal of power angle calculator 220 (described in detail herein).Delay Compensate element 218 or 224 is fed the output of the low passfilter 216 or 222 respectively where the signal or an estimate of thesignal from the respective filter is extrapolated in time such that thedelay resulting from the low pass filtering operation is removed. Thecalculator 220 output is the power angle (φ). The output of delaycompensate 218 is the delay compensated linear phase low pass filteredArmature reactive demand signal (Q_(LP)). The output of delay compensate224 is the delay compensated linear phase low pass filtered Armaturereal demand signal (P_(LP)).

The Power variance elements 205 includes high pass filter 226 coupled inseries via variance element 228, to low pass filter 230. The output ofthe low pass filter 230 is the P_(VAR) signal. Power variance elements205 also includes high pass filter 232 coupled in series with envelopeelement 234 and low pass filter to delay compensate element 238. Inenvelope element 234, the signal is formed into a peak envelope withspecified peak decay characteristics. Delay compensate element 238 isfed the output of the low pass filter 230 where the signal or anestimate of the signal from the respective filter is extrapolated intime such that the delay resulting from the low pass filtering operationis removed. The output of element 238 is the P_(PK) signal.

Referring to FIG. 2 b, elements 207 includes the V_(AVG), power angle(φ), signal Q_(LP) and signal P_(LP) (See FIG. 2 a), and machineparameters (as defined herein) are applied to Blondel-Park synchronousmachine model 240 to generate a pull-out torque indication signal (whichis applied in FIG. 2 c to element 260). The Blondel-Park model forsynchronous machines as it is known today emerged principally from tworeferences: “Synchronous Machines”, a classic engineering book by A. E.Blondel, published in English in 1913, and “Two-Reaction Theory ofSynchronous Machines”, a technical paper by R. H. Park, published in1929.

The Blondel-Park model is also sometimes referred to as the two-reactionmodel, or more frequently as the Direct-Quadrature model, since the tworeactions discussed in these classic references refer to the componentsof machine rotor currents and EMFs resolved along orthogonal axes as therotor magnetic field poles. The formulation discussed herein will usethe Direct-Quadrature model (DQ) nomenclature. Detailed explanations andexemplary interpretations for the parameters defined and used in thisformulations may be obtained from either of these classic references, oralternatively from a vast array of modern references on the subject ofelectric motors and generators; see for example: Fitzgerald, Kingsley,and Umans, “Electric Machinery”, McGraw-Hill 2003, ISBN 0073660094.

Estimation of the Synchronous Machine Pull-Out Torque Using DQParameters.

The synchronous machine structural and behavioral parameters will bespecified using the per-unit system, additional definitions (in additionto the definitions provided previously in the description) andabbreviations as follows:

Although an exemplary three-phase calculation is shown, the number ofphases can be changed to any number by changing only one formula forV_(ARM) The abbreviation ‘pu’ shall indicate a per-unit quantity.

Additional Definitions

These quantities are typically provided by the synchronous machinemanufacturer:

M_(BASE): Machine basis torque, as N-m or lb-ft

M_(PULL): Machine pull-out torque, as N-m or lb-ft

N_(BASE): Machine basis rotation speed, as RPM

V_(BASE): Machine basis voltage, phase to neutral

R_(A): Armature winding resistance, pu

X_(D): Direct axis unsaturated reactance, pu

X_(Q): Quadrature axis unsaturated reactance, pu

I_(S): Armature saturation current magnitude, pu

These quantities are measured during synchronous machine operation:

Q_(LP): Low pass filtered reactive power demand, VAR

P_(LP): Low pass filtered real power demand, Watts

V_(AVG): Low pass filtered average phase to phase voltage measured atthe machine terminals, Volts

$\Phi = {{\tan^{- 1}\left( \frac{Q_{LP}}{P_{LP}} \right)}\text{:}}$Power angle, also Known as power factor angle

These quantities are calculated for the estimation of the pull-outtorque:

V_(ARM)=V_(AVG)/(√{square root over (3)}V_(BASE)): Equivalent averagearmature voltage, pu

I_(D): Direct axis current phasor, pu

E_(Q): Quadrature axis voltage, pu

E_(F): Direct axis effective voltage, pu

δ₀: Rotor torque angle, radians, initial estimate

δ₁: Rotor torque angle, radians, iterated estimate

j=√{square root over (−1)}: Base imaginary number for complex notation

S₁: Apparent power component of torque angle, pu

S₂: Apparent power component of twice torque angle, pu

ƒ( ): Rotor torque angle iteration function

These quantities are General mathematical nomenclature:

j=√{square root over (−1)}: Base imaginary number for complex notation

Im( ): Imaginary part of a complex number

Re( ): Real part of a complex number

Euler notation is described for complex quantities in the calculationprocedure outlined here.

Calculation Procedure

Part 1: Static Computations

E_(Q) = I_(S)(cos  Φ + j sin  Φ)(R_(A) + j X_(Q)) + V_(ARM)$S_{2} = {V_{ARM}^{2}\frac{\left( {X_{D} - X_{Q}} \right)}{2\; X_{D}X_{Q}}}$$\delta_{1} = {\tan^{- 1}\left( \frac{{Im}\left( E_{Q} \right)}{{Re}\left( E_{Q} \right)} \right)}$Part 2: Iterated Computations

δ₀ = f(δ₁)$I_{D} = {I_{S}{\sin\left( {\Phi + \delta_{0}} \right)}\left( {{\cos\left( {\delta_{0} - \frac{\pi}{2}} \right)} + {j\;{\sin\left( {\delta_{0} - \frac{\pi}{2}} \right)}}} \right)}$E_(F) = E_(Q) + j I_(D)(X_(D) − X_(Q))$S_{1} = {{E_{F}}\frac{V_{ARM}}{X_{D}}}$$\delta_{1} = {\cos^{- 1}\left( \frac{\sqrt{S_{1}^{2} + {32\; S_{2}^{2}}} - S_{1}}{8\; S_{2}} \right)}$Part 3: Final ComputationsM _(PULL) =M _(BASE)(S ₁ sin(δ₁)+S ₂ cos(2δ₁))

The iteration function may be used in stabilizing iterative proceduresand in improving final result convergence. This function may be, forexample, one of: (i) simple substitution of the new estimate into theiteration function output, (ii) weighted step, in which some part of thedifference between the present and prior results is applied to theiteration function output, or (iii) a projection algorithm whichextrapolates (projects) a new iteration function output depending on twoor more prior outputs. The iteration function also terminates theIteration Computations when the difference between the present and priorestimates is suitably small, indicating convergence.

The P_(LP) and the P_(PK) signal are summed with summation element 242and applied to power to torque converter 244, which generates aconverted torque signal. The converted torque signal is fed via loadtorque peak envelope element 246 to select maximum detector 258.

A pre-specified confidence level indication signal is provided to aprobability distribution element 250. Element 250 then generates aconstant corresponding to the confidence that is multiplied by the valuefor P_(VAR) in multiplier Element 252. The output multiplied value isthen fed to summation Element 248 where it is summed with the P_(LP)signal. The summed signal is then fed to the power to torque converterElement 254 and subsequently processed by a process variance torqueElement 256. The processed converted signal is then fed to the selectmaximum detector 258 where it is compared against the converted torquesignal from the load torque peak envelop Element 246. The maximum signalof the two signals is then provided from the torque Element 256. Theprocessed converted signal is then fed to the select as an estimatedmaximum torque signal (M_(LOAD)).

Adjustment decision processor includes circuits and elements describedin FIGS. 2 c-2 e. Referring to FIG. 2 c, the estimated maximum torque(M_(LOAD)) is then applied to the summation element 260 with theestimated pull out torque signal (M_(PULL)). Summation element 260subtracts the M_(LOAD) from M_(PULL) and provides the difference betweenthe signals (AM) to Comparators 262 and 264. The Specified Torque MarginUpper Bound is fed to Comparator 262 and is compared with signal (AM).The output of the comparator 262 is fed to element 266 along with thepower angle (Φ) signal, and the M_(LOAD), to compute an estimate of therequired armature voltage. The Specified Torque Margin Lower Bound isfed to Comparator 264 and is compared with (ΔM). The output of thecomparator 264 is fed to element 266 along with the power angle (Φ)signal, and the M_(LOAD), to compute an estimate of the requiredarmature voltage. Element 266 and 268 computes an estimate of therequired armature voltage using the formulas set forth below.

The calculation of synchronous machine torques in operation using the DQmodel includes nonlinear dependence on the armature voltage, the machinereal power demand, and the machine reactive power demand. The inversecalculation of the required armature voltage for a specified torque thusrequires the inversion of nonlinear functions, which may not bepractical in many real time control applications. However, some limitedregimes of the associated nonlinearities may be suitably approximated bylinear functions. Such linear functions may be estimated, for example,by means of linear regression on the nonlinear functions as illustratedusing the following Computation for V_(EST). The approximating linearfunction obtained by linear regression is completely defined by itsregression coefficients, identified as the β coefficients, discussedbelow.

Definitions:

Quantities associated with limited regime approximation of voltage

M_(LOAD): Specified load torque of interest, N-m

V_(EST): Estimated armature voltage for a specified load torque undergiven operating conditions, Volts

β₀: Regression constant, Volts

β₁₀₁: Regression factor for power angle, Volts/radian

β_(M): Regression factor for load torque, Volts/N-m

Computation

V_(EST)=β₀+β_(Φ)Φ+β_(M)M_(LOAD), where coefficients β must be estimatedfor each synchronous machine of interest.

The estimated required armature voltage from element 266 is provided asa decrease indication signal V_(DEC) to comparator 276 and summationelement 274 (FIG. 2 d), and the estimated required armature voltage fromelement 268 is provided as an increase indication signal V_(DEC) tosummation element 292 (FIG. 2 e).

Referring to FIG. 2 d, the specified minimum voltage indication signalV_(MIN) is fed to one terminal of comparator 276 and the requiredarmature voltage signal V_(DEC) is fed to the other terminal ofcomparator 276 and summation element 274. Comparator 276 provides apositive indication signal to AND gate 282 only if signal V_(DEC) isgreater than signal V_(MIN).

Regulator Tap Voltage Step signal ΔV_(TAP) is provided to multiplierelement 270 where it is divided in half and fed to summation element272. Processed signal V_(AVG) is also applied to Summation element 272.Summation element 272 subtracts signal ΔV_(TAP) from signal V_(AVG) andthe difference is applied to summation element 274. Required ArmatureVoltage V_(DEC) is also applied to Summation element 274. Summationelement 274 subtracts the output signal of element 272 from V_(DEC) andapplies the difference as signal ΔV to threshold detector 278. Theoutput of Threshold detector 278 triggers (providing a positiveindication) if ΔV is less than 0 and is applied to AND gate 282.

Measured Regulator Tap setting signal Z_(REG) and Specified Minimum TapSetting signal Z_(MIN) is applied to Comparator 280. When Z_(REG) isgreater than Z_(MIN), comparator 280 is triggered providing a positiveindication signal to AND gate 282. When a positive indication signal isprovided on all inputs to AND gate 282, AND gate triggers resulting in aRegulator tap decrease signal being fed to voltage regulator transformer106 via regulator interface 110.

Referring to FIG. 2 e, the Measured Regulator Tap setting Z_(REG) andthe Specified Maximum tap setting Z_(MAX) is applied to comparator 286.Comparator 286 provides a positive indication signal only if the Z_(MAX)is less than Z_(REG), and feeds the indication signal to AND gate 296.

Regulator Tap Voltage Step signal ΔV_(TAP) is provided to multiplierelement 288 where it is divided in half and fed to summation element290. Processed signal V_(AVG) is also applied to Summation element 290.Summation element 290 subtracts divided signal ΔV_(TAP) from signalV_(AVG), and the difference is applied to summation element 292. SignalV_(INC) is also applied to summation element 292. Summation element 292subtracts the output of element 290 from signal V_(INC) and applies thedifference as signal ΔV to threshold detector 294. The output ofThreshold detector 294 triggers (providing a positive indication) ifsignal ΔV is less than 0 and is applied as a positive indication(logical TRUE state) to AND gate 296. When a positive indication isprovided on all inputs to AND gate 296, AND gate 296 triggers resultingin a Regulator tap increase signal being fed to voltage regulatortransformer 106 via regulator interface 110.

Example Voltage Controller Architecture

In FIG. 3 are illustrated selected modules in Voltage Controller 300using an optional process 400 shown in FIG. 4. Voltage Controllerreceives Signals from voltage signal processing element 126 and feedssignals to regulator interface 110. Voltage Controller 300 hasprocessing capabilities and memory suitable to store and executecomputer-executable instructions. In one example, Voltage Controller 300includes one or more processors 304 and memory 312.

The memory 322 may include volatile and nonvolatile memory, removableand non-removable media implemented in any method or technology forstorage of information, such as computer-readable instructions, datastructures, program modules or other data. Such memory includes, but isnot limited to, RAM, ROM, EEPROM, flash memory or other memorytechnology, CD-ROM, digital versatile disks (DVD) or other opticalstorage, magnetic cassettes, magnetic tape, magnetic disk storage orother magnetic storage devices, RAID storage systems, or any othermedium which can be used to store the desired information and which canbe accessed by a computer system.

Stored in memory 322 of the Voltage Controller 300 may include a realtime operating system 314, an I/O controller 316, a confidence store318, and an adjustment decision application 320. Real time operatingsystem 314 may be used by adjustment decision application 320 to operatecontroller 300. I/O controller may provide drivers for Voltagecontroller to communicate with Voltage signal processor or regulatorinterface. A confidence store 318 may include preconfigured parameters(or set by the user before or after initial operation) such a confidencevalues, electrical device operating parameters, voltage levels, machineoperating parameters and probabilities. Such values may be updatethrough an interface with the user directly to the voltage controller(not shown).

Although determining a voltage adjustment decision is described usingelements described in FIGS. 2 a-2 e, alternatively a process fordetermining a voltage adjustment decision may also be implemented usingan exemplary optional process 400. The exemplary process 400 may be acollection of blocks in a logical flow diagram, which represents asequence of operations that can be implemented in hardware, software,and a combination thereof. In the context of software, the blocks mayrepresent computer-executable instructions that, when executed by one ormore processors, perform the recited operations. Generally,computer-executable instructions include routines, programs, objects,components, data structures, and the like that perform particularfunctions or implement particular abstract data types. The order inwhich the operations are described is not intended to be construed as alimitation, and any number of the described blocks can be combined inany order and/or in parallel to implement the process.

Referring to FIG. 4, a process 400 is shown for determining a voltageadjustment decision by adjustment decision processor circuit 128 usingthe processor 300 and modules 314-320 shown in FIG. 3. In the process,the selected voltage signal is received from the voltage signalprocessing element 126 (FIG. 1) or alternatively directly frommonitoring device 118 in block 402. In block 402, processor 300determines an applied armature voltage supplied to the polyphasesynchronous machine 119 (FIG. 1).

The processor 300, in block 404, changes the armature voltage beingsupplied from the power source to the machine 119 by selecting one ofthe voltage levels from the taps of the regulating transformer 106. Adetermination is made in block 406 based on a confidence level andestimates (determined as described previously) will the pull-out torqueof the machine be exceeded.

If the pull-out torque of the machine cannot be exceeded, adetermination is made in block 408 as to whether the voltage levels fromthe taps of the regulating transformer 106 can be lowered.

If the voltage levels can be lowered or if based on the confidence levelthe pull out torque of the machine will be exceeded, the an indicationsignal is sent via regulator interface 110 to voltage regulatingtransformer 106 to change the tap position (increase or decrease the tapposition using the techniques previously described). After blocks 408and 410 are executed, the process repeats in block 402 where processor300 determines an applied armature voltage supplied to the polyphasesynchronous machine 119.

Referring to FIG. 5, diagram 500 is shown having cumulative probabilitydistribution curve 502 illustrating a typical probability distributionof the voltage control system that is used to select a weighting factorthat is used in estimating voltage deviations. The x-axis corresponds toa unit random variable and the y-axis corresponds to a probability. Inone implementation a “Tail Probability” 504 or (1−p) is computed usingthe formula “p=(1−a)/2”, where “a” is the specified confidence level and“p” is the tail probability. A “Weighting Factor” 506 is the value ofthe unit random variable (also generally referred to as “normalized”) aslocated on the Probability Distribution corresponding to the TailProbability. Although a typical probability distribution is shown, theparticular probability distribution that is applied may vary dependingon the properties of the electrical load for the electrical orelectronic devices.

From the foregoing, it is apparent the description provides systems,processes and apparatus which can be utilized to monitor and manageelectrical power distribution. Further, the disclosed systems, processesand apparatus permit power conservation by maintaining deliveredvoltages near levels that optimize the efficiency of the connectedelectrical and electronic devices and also can provide more robust powerdelivery under inclement power system loading conditions. In addition,the systems, processes and apparatus of the present system are costeffective when compared with other power management devices. In contrastto prior art systems, the present systems, processes and apparatusprovide infinite variability of system parameters, such as multiple,different delivered voltage levels, within predetermined limits. Forexample, all users can be incrementally adjusted up or down together, orsome users may be adjusted to a first degree while other users areadjusted to another degree or to separate, differing degrees. Suchadvantageously provides new flexibility in power distribution control,in addition to providing new methods of adjustment.

While the above detailed description has shown, described and identifiedseveral novel features of the invention as applied to a preferredembodiment, it will be understood that various omissions, substitutionsand changes in the form and details of the described embodiments may bemade by those skilled in the art without departing from the spirit ofthe invention. Accordingly, the scope of the invention should not belimited to the foregoing discussion, but should be defined by theappended claims.

What is claimed is:
 1. A method comprising: determining an appliedarmature voltage supplied to a polyphase synchronous machine having apull-out torque, the armature voltage supplied from a power source viaone of a plurality of taps of a regulating transformer, a first tap ofthe plurality of taps configured to supply a voltage at a differentlevel than a second tap of the plurality of taps; selecting the secondtap to supply the armature voltage based on the determined appliedarmature voltage, power consumption of the machine, and a confidencelevel that the pull-out torque is not exceeded, wherein the confidencelevel corresponds to a probability distribution indicative of at leastone operating characteristic of the polyphase synchronous machine; andresponsive to a slip of the polyphase synchronous machine, increasing amargin of the pull-out torque.
 2. The method of claim 1, furthercomprising: continuously determining the applied armature voltagesupplied to the polyphase synchronous machine.
 3. The method of claim 1,wherein the selected confidence level is applied to a statistic of thetime varying mechanical load applied to the polyphase synchronousmachine.
 4. The method of claim 1, further comprising: determining aslip of the polyphase synchronous machine.
 5. The method of claim 1,further comprising: determining a mechanical torque demand; andcomparing the mechanical torque demand against a predetermined torque.6. The method of claim 5, further comprising: determining an optimumarmature voltage level corresponding to the predetermined torque.
 7. Themethod of claim 5, wherein determining the mechanical torque demand isbased on a measurement of the machine actual load.
 8. The method ofclaim 7, further comprising: determining the maximum mechanical torquedemand in real time.
 9. The method of claim 1, further comprising:setting the armature voltage to be supplied to the machine to cause thepull-out torque of the machine to be greater than a maximum mechanicaltorque demand.
 10. The method of claim 1, further comprising: specifyinga margin of the pull-out torque with an upper and a lower bound todecrease a frequency of armature voltage changes.
 11. The method ofclaim 1, wherein the selecting the second tap comprises: determining asuitably smooth estimate of the mechanical load torque using a realpower demand signal observed at armature terminals of the polyphasesynchronous machine; determining a pull-out torque of the machine usingphysical parameters of the polyphase synchronous machine, a real andreactive power observed at the armature terminals, and the appliedarmature voltage; and comparing a difference in the mechanical loadtorque and the pull-out torque against a pre-defined margin boundary.12. A method comprising: receiving, by a voltage signal processor, anindication of an armature voltage, real power and reactive powermonitored at an armature of a synchronous machine; determining acharacteristic of the synchronous machine based on the receivedindication, the characteristic comprising a maximum mechanical torquedemand; and adjusting, based on the determined characteristic and aconfidence level that a pull-out torque of the synchronous machine willnot be exceeded, the armature voltage supplied to the synchronousmachine.
 13. The method of claim 12, wherein the characteristiccomprises a slip of the synchronous machine.
 14. The method of claim 13,further comprising: responsive to determining the slip of thesynchronous machine, increasing a margin of a pull-out torque.
 15. Themethod of claim 12, further comprising: specifying a margin of thepull-out torque with an upper and a lower bound to decrease a frequencyof armature voltage changes.
 16. The method of claim 12, furthercomprising: determining a suitably smooth estimate of a mechanical loadtorque using a real power demand signal monitored at the armature of thesynchronous machine; determining an estimated pull-out torque of themachine using physical parameters of the synchronous machine, the realand reactive power monitored at the armature, and the applied armaturevoltage; and comparing a difference in the estimate of the mechanicalload torque and the estimated pull-out torque against a pre-definedmargin boundary.
 17. The method of claim 12, further comprising:adjusting the armature voltage to be supplied to the machine to cause apull-out torque of the machine is greater than a maximum mechanicaltorque demand.
 18. The method of claim 12, wherein adjusting thearmature voltage further comprises: selecting a first tap of aregulating transformer supplying power from a power source.
 19. Themethod of claim 18, further comprising: selecting a second tap of theregulating transformer, the second tap configured to supply voltage at adifferent level than the first tap.
 20. The method of claim 12, furthercomprising: determining the characteristic based on a measurement of themachine actual mechanical load torque.